Your search keyword '"Ricardo S. Ramiro"' showing total 8 results

1. Host lung microbiota promotes malaria-associated acute respiratory distress syndrome

Author

Debanjan Mukherjee, Ângelo Ferreira Chora, Jean-Christophe Lone, Ricardo S. Ramiro, Birte Blankenhaus, Karine Serre, Mário Ramirez, Isabel Gordo, Marc Veldhoen, Patrick Varga-Weisz, and Maria M. Mota

Subjects

Disease Models, Animal, Respiratory Distress Syndrome, Multidisciplinary, Plasmodium berghei, Microbiota, General Physics and Astronomy, Animals, General Chemistry, Lung, General Biochemistry, Genetics and Molecular Biology, Malaria

Abstract

Severe malaria can manifest itself with a variety of well-recognized clinical phenotypes that are highly predictive of death – severe anaemia, coma (cerebral malaria), multiple organ failure, and respiratory distress. The reasons why an infected individual develops one pathology rather than another remain poorly understood. Here we use distinct rodent models of infection to show that the host microbiota is a contributing factor for the development of respiratory distress syndrome and host mortality in the context of malaria infections (malaria-associated acute respiratory distress syndrome, MA-ARDS). We show that parasite sequestration in the lung results in sustained immune activation. Subsequent production of the anti-inflammatory cytokine IL-10 by T cells compromises microbial control, leading to severe lung disease. Notably, bacterial clearance with linezolid, an antibiotic commonly used in the clinical setting to control lung-associated bacterial infections, prevents MA-ARDS-associated lethality. Thus, we propose that the host’s anti-inflammatory response to limit tissue damage can result in loss of microbial control, which promotes MA-ARDS. This must be considered when intervening against life-threatening respiratory complications.

Published

2022

2. Host miRNA-21 promotes liver dysfunction by targeting small intestinal

Author

André A, Santos, Marta B, Afonso, Ricardo S, Ramiro, David, Pires, Madalena, Pimentel, Rui E, Castro, and Cecília M P, Rodrigues

Subjects

Liver Cirrhosis, Mice, Knockout, Cholestasis, gut microbiota, digestive system, Gastrointestinal Microbiome, Mice, Inbred C57BL, Lactobacillus, Mice, MicroRNAs, Liver, miRNAs, Animals, Dysbiosis, Female, Lactic Acid, D-lactate, small intestinal homeostasis, Research Article, Research Paper

Abstract

New evidence shows that host-microbiota crosstalk can be modulated via endogenous miRNAs. We have previously reported that miR-21 ablation protects against liver injury in cholestasis. In this study, we investigated the role of miR-21 in modulating the gut microbiota during cholestasis and its effects in liver dysfunction. Mice lacking miR-21 had reduced liver damage and were protected against small intestinal injury as well as from gut microbiota dysbiosis when subjected to bile duct ligation surgery. The unique microbiota profile of miR-21KO mice was characterized by an increase in Lactobacillus, a key microbiome genus for gut homeostasis. Interestingly, in vitro incubation of synthetic miR-21 directly reduced Lactobacillus load. Moreover, supplementation with Lactobacillus reuteri revealed reduced liver fibrosis in acute bile duct-ligated mice, mimicking the protective effects in miR-21 knockout mice. D-lactate, a main product of Lactobacillus, regulates gut homeostasis that may link with reduced liver fibrosis. Altogether, our results demonstrate that miR-21 promotes liver dysfunction through direct modulation of the gut microbiota and highlight the potential therapeutic effects of Lactobacillus supplementation in gut and liver homeostasis.

Published

2020

3. Low mutational load and high mutation rate variation in gut commensal bacteria

Author

Claudia Bank, Isabel Gordo, Paulo Durão, and Ricardo S. Ramiro

Subjects

0301 basic medicine, Male, Mutation rate, Gut flora, Biochemistry, Mice, 0302 clinical medicine, Mutation Rate, Biology (General), 2. Zero hunger, Genetics, Mammals, Insertion Mutation, biology, General Neuroscience, Escherichia coli Proteins, Eukaryota, Nonsense Mutation, Phenotype, Adaptation, Physiological, Anti-Bacterial Agents, Fixation (population genetics), Deletion Mutation, Vertebrates, Microorganisms, Genetically-Modified, General Agricultural and Biological Sciences, Research Article, Yellow Fluorescent Protein, QH301-705.5, In silico, Nonsense mutation, Research and Analysis Methods, Rodents, Microbiology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Molecular evolution, Escherichia coli, Animals, Selection, Genetic, Molecular Biology Techniques, Molecular Biology, DNA Polymerase III, Genetic diversity, Evolutionary Biology, General Immunology and Microbiology, Organisms, Biology and Life Sciences, Proteins, biology.organism_classification, Organismal Evolution, Gastrointestinal Microbiome, Mice, Inbred C57BL, Luminescent Proteins, 030104 developmental biology, Mutation, Amniotes, Microbial Evolution, 030217 neurology & neurosurgery, Cloning

Abstract

Bacteria generally live in species-rich communities, such as the gut microbiota. Yet little is known about bacterial evolution in natural ecosystems. Here, we followed the long-term evolution of commensal Escherichia coli in the mouse gut. We observe the emergence of mutation rate polymorphism, ranging from wild-type levels to 1,000-fold higher. By combining experiments, whole-genome sequencing, and in silico simulations, we identify the molecular causes and explore the evolutionary conditions allowing these hypermutators to emerge and coexist within the microbiota. The hypermutator phenotype is caused by mutations in DNA polymerase III proofreading and catalytic subunits, which increase mutation rate by approximately 1,000-fold and stabilise hypermutator fitness, respectively. Strong mutation rate variation persists for >1,000 generations, with coexistence between lineages carrying 4 to >600 mutations. The in vivo molecular evolution pattern is consistent with fitness effects of deleterious mutations sd ≤ 10−4/generation, assuming a constant effect or exponentially distributed effects with a constant mean. Such effects are lower than typical in vitro estimates, leading to a low mutational load, an inference that is observed in in vivo and in vitro competitions. Despite large numbers of deleterious mutations, we identify multiple beneficial mutations that do not reach fixation over long periods of time. This indicates that the dynamics of beneficial mutations are not shaped by constant positive Darwinian selection but could be explained by other evolutionary mechanisms that maintain genetic diversity. Thus, microbial evolution in the gut is likely characterised by partial sweeps of beneficial mutations combined with hitchhiking of slightly deleterious mutations, which take a long time to be purged because they impose a low mutational load. The combination of these two processes could allow for the long-term maintenance of intraspecies genetic diversity, including mutation rate polymorphism. These results are consistent with the pattern of genetic polymorphism that is emerging from metagenomics studies of the human gut microbiota, suggesting that we have identified key evolutionary processes shaping the genetic composition of this community., Weak-effect deleterious mutations and negative frequency–dependent selection, acting on beneficial mutations, shape the dynamics of molecular evolution within the mouse gut microbiota.

Published

2020

4. Diet leaves a genetic signature in a keystone member of the gut microbiota

Author

Tanja Dapa, Ricardo S. Ramiro, Karina B. Xavier, Isabel Gordo, and Miguel F. Pedro

Subjects

Dietary Fiber, History, Polymers and Plastics, Gut flora, Diet, High-Fat, digestive system, Microbiology, Industrial and Manufacturing Engineering, Mice, Genetic signature, Virology, medicine, Animals, Humans, Colonization, Business and International Management, Genetics, Genetic diversity, biology, Bacteroidetes, medicine.disease, biology.organism_classification, Diet, Gastrointestinal Microbiome, Bacteroides thetaiotaomicron, Biomarker, microbiota, high-fat high-sugar diet, Western-style diet, microbiota evolution, gut dysbiosis, Bacteroides thetaiotaomicron, Bacteroidetes, gut metabolon, gut ecology, multi-omics analyses, Dysbiosis, Parasitology

Abstract

Switching from a low-fat and high-fiber diet to a Western-style high-fat and high-sugar diet causes microbiota imbalances that underlay many pathological conditions (i.e., dysbiosis). Although the effects of dietary changes on microbiota composition and functions are well documented, their impact in gut bacterial evolution remains unexplored. We followed the emergence of mutations in Bacteroides thetaiotaomicron, a prevalent fiber-degrading microbiota member, upon colonization of the murine gut under different dietary regimens. B. thetaiotaomicron evolved rapidly in the gut and Western-style diet selected for mutations that promote degradation of mucin-derived glycans. Periodic dietary changes caused fluctuations in the frequency of such mutations and were associated with metabolic shifts, resulting in the maintenance of higher intraspecies genetic diversity compared to constant dietary regimens. These results show that dietary changes leave a genetic signature in microbiome members and suggest that B. thetaiotaomicron genetic diversity could be a biomarker for dietary differences among individuals. info:eu-repo/semantics/publishedVersion

Published

2022

5. Evolution of commensal bacteria in the intestinal tract of mice

Author

Ana E. Sousa, Ricardo S. Ramiro, Nelson Frazão, and Isabel Gordo

Subjects

Commensal bacteria, 0301 basic medicine, Microbiology (medical), mice, Bacterial Species, Adaptation, Biological, Gut flora, Microbiology, Evolution, Molecular, 03 medical and health sciences, Mice, Antibiotic resistance, Symbiosis, Animals, gut microbiota, biology, Bacteria, Host (biology), Ecology, Species diversity, biology.organism_classification, Commensalism, Gastrointestinal Tract, 030104 developmental biology, Infectious Diseases, Evolutionary biology, Mutation, Adaptation, Evolutionary change

Abstract

The deposited article is a post-print version and has been submitted to peer review. This deposit is composed by the main article, and it hasn't any supplementary materials associated. This publication hasn't any creative commons license associated. Hundreds of different bacterial species inhabit our intestines and contribute to our health status, with significant loss of species diversity typically observed in disease conditions. Within each microbial species a great deal of diversity is hidden and such intra-specific variation is also key to the proper homeostasis between the host and its microbial inhabitants. Indeed, it is at this level that new mechanisms of antibiotic resistance emerge and pathogenic characteristics evolve. Yet, our knowledge on intra-species variation in the gut is still limited and an understanding of the evolutionary mechanisms acting on it is extremely reduced. Here we review recent work that has begun to reveal that adaptation of commensal bacteria to the mammalian intestine may be fast and highly repeatable, and that the time scales of evolutionary and ecological change can be very similar in these ecosystems. Deutsche Forschungsgemeinschaft Grant SFB 680 and the Portuguese Science and Technology Foundation FCT (SFRH/BPD/111725/2015 and UID/BIM/04501/2013 support to AS, SFRH/BPD/110750/2015 support to NF). info:eu-repo/semantics/publishedVersion

Published

2017

6. A Mutational Hotspot and Strong Selection Contribute to the Order of Mutations Selected for during Escherichia coli Adaptation to the Gut

Author

Marta Lourenço, Ricardo S Ramiro, Daniela Güleresi, João Barroso-Batista, Karina B Xavier, Isabel Gordo, and Ana Sousa

Subjects

0301 basic medicine, Cancer Research, Mutation rate, Natural selection, Evolutionary adaptation, medicine.disease_cause, Biochemistry, Mice, Nucleic Acids, Natural Selection, Genetics (clinical), Dicarboxylic Acid Transporters, Genetics, Mutation, Insertion Mutation, Nonsense mutation, Insertion mutation, Microbial evolution, Clonal interference, Escherichia coli Proteins, Nonsense Mutation, Adaptation, Physiological, Deletion Mutation, Deletion mutation, Research Article, Evolutionary Processes, lcsh:QH426-470, 030106 microbiology, Biology, Research and Analysis Methods, Microbiology, Evolution, Molecular, 03 medical and health sciences, Adaptive mutation, Evolutionary Adaptation, Genetic variation, Escherichia coli, medicine, Animals, Selection, Genetic, Molecular Biology Techniques, Operons, Molecular Biology, Alleles, Ecology, Evolution, Behavior and Systematics, Evolutionary Biology, Population Biology, Genetic Variation, Membrane Transport Proteins, Biology and Life Sciences, Epistasis, Genetic, DNA, Organismal Evolution, Gastrointestinal Microbiome, lcsh:Genetics, 030104 developmental biology, Microbial Evolution, Epistasis, Adaptation, Population Genetics, Cloning

Abstract

The relative role of drift versus selection underlying the evolution of bacterial species within the gut microbiota remains poorly understood. The large sizes of bacterial populations in this environment suggest that even adaptive mutations with weak effects, thought to be the most frequently occurring, could substantially contribute to a rapid pace of evolutionary change in the gut. We followed the emergence of intra-species diversity in a commensal Escherichia coli strain that previously acquired an adaptive mutation with strong effect during one week of colonization of the mouse gut. Following this first step, which consisted of inactivating a metabolic operon, one third of the subsequent adaptive mutations were found to have a selective effect as high as the first. Nevertheless, the order of the adaptive steps was strongly affected by a mutational hotspot with an exceptionally high mutation rate of 10−5. The pattern of polymorphism emerging in the populations evolving within different hosts was characterized by periodic selection, which reduced diversity, but also frequency-dependent selection, actively maintaining genetic diversity. Furthermore, the continuous emergence of similar phenotypes due to distinct mutations, known as clonal interference, was pervasive. Evolutionary change within the gut is therefore highly repeatable within and across hosts, with adaptive mutations of selection coefficients as strong as 12% accumulating without strong constraints on genetic background. In vivo competitive assays showed that one of the second steps (focA) exhibited positive epistasis with the first, while another (dcuB) exhibited negative epistasis. The data shows that strong effect adaptive mutations continuously recur in gut commensal bacterial species., Author Summary The relative contribution of random loss and migration versus de novo mutation to the overall diversity of the gut microbiota is far from understood. Population sizes of bacterial communities inhabiting the gut can be very large and therefore, both weak and strong effect beneficial mutations theoretically have the opportunity to contribute to adaptation. Here, by discretizing the adaptive steps that occur during colonization by a gut commensal, we uncover a mutational hotspot, large effect mutations and different forms of natural selection as the core ingredients to the emergence of diversity in this environment. We show that, on occasion, strong periodic selection can create and reduce diversity but then recurrent mutation generates new adaptive variants that compete for fixation. Selection for keeping particular adaptive variants at low frequency, balancing selection, was also shown to be pervasive. Unexpectedly, given the complexity of the gut ecosystem, we find a highly repeatable evolutionary process, motivated by a mutational hotspot and strong effect adaptive mutations continuously recurring in commensal bacterial species.

Published

2016

7. The Genetic Basis of Escherichia coli Pathoadaptation to Macrophages

Author

Migla Miskinyte, Ana Sousa, Ricardo S Ramiro, Jorge A Moura de Sousa, Jerzy Kotlinowski, Iris Caramalho, Sara Magalhães, Miguel P Soares, and Isabel Gordo

Subjects

Male, Transposable element, QH301-705.5, Immunology, Adaptation, Biological, Virulence, HIV Infections, Bacterial genome size, Biology, medicine.disease_cause, Microbiology, Mice, 03 medical and health sciences, Virology, Genetics, medicine, Escherichia coli, Animals, Insertion, Biology (General), Molecular Biology, Gene, Cells, Cultured, Immune Evasion, 030304 developmental biology, 0303 health sciences, Experimental evolution, Innate immune system, 030306 microbiology, Macrophages, Genetic Variation, RC581-607, Immunity, Innate, Mice, Inbred C57BL, Phenotype, Parasitology, Genetic Fitness, Immunologic diseases. Allergy, Research Article

Abstract

Antagonistic interactions are likely important driving forces of the evolutionary process underlying bacterial genome complexity and diversity. We hypothesized that the ability of evolved bacteria to escape specific components of host innate immunity, such as phagocytosis and killing by macrophages (MΦ), is a critical trait relevant in the acquisition of bacterial virulence. Here, we used a combination of experimental evolution, phenotypic characterization, genome sequencing and mathematical modeling to address how fast, and through how many adaptive steps, a commensal Escherichia coli (E. coli) acquire this virulence trait. We show that when maintained in vitro under the selective pressure of host MΦ commensal E. coli can evolve, in less than 500 generations, virulent clones that escape phagocytosis and MΦ killing in vitro, while increasing their pathogenicity in vivo, as assessed in mice. This pathoadaptive process is driven by a mechanism involving the insertion of a single transposable element into the promoter region of the E. coli yrfF gene. Moreover, transposition of the IS186 element into the promoter of Lon gene, encoding an ATP-dependent serine protease, is likely to accelerate this pathoadaptive process. Competition between clones carrying distinct beneficial mutations dominates the dynamics of the pathoadaptive process, as suggested from a mathematical model, which reproduces the observed experimental dynamics of E. coli evolution towards virulence. In conclusion, we reveal a molecular mechanism explaining how a specific component of host innate immunity can modulate microbial evolution towards pathogenicity., Author Summary The selective pressure imposed by the host immune system is an important component of microbial adaptation from commensalism to pathogenicity. We used experimental evolution to study the initial steps of the adaptation of Escherichia coli to cells of the innate immune system, i.e., macrophages. Our results demonstrate that bacteria can evolve remarkably fast, and acquire adaptations increasing survival inside macrophages and/or ability to escape engulfment. The mechanism underlying this pathoadaptive process involves the accumulation of mutations caused by transposon insertions, increasing pathogenicity in vivo. These findings reveal the remarkable fast pace at which bacteria can evolve to escape a central component of the host innate immunity, namely macrophages.

Published

2013

8. Molecular evolution and phylogenetics of rodent malaria parasites

Author

Sarah E. Reece, Darren J. Obbard, and Ricardo S. Ramiro

Subjects

0106 biological sciences, Plasmodium, Rodent malaria, Time Factors, Plasmodium berghei, Protozoan Proteins, Subspecies, 01 natural sciences, Phylogeny, 0303 health sciences, biology, 3. Good health, Plasmodium chabaudi, Plasmodium yoelii, Research Article, Genotype, Evolution, Molecular Sequence Data, Rodentia, 010603 evolutionary biology, Host-Parasite Interactions, Evolution, Molecular, 03 medical and health sciences, Molecular evolution, Phylogenetics, parasitic diseases, medicine, Species delimitation, QH359-425, Animals, Divergence time, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Models, Genetic, Human evolutionary genetics, Genetic Variation, Bayes Theorem, Sequence Analysis, DNA, DNA, Protozoan, medicine.disease, biology.organism_classification, Malaria, Parasitology, Evolutionary biology

Abstract

Background Over the last 6 decades, rodent Plasmodium species have become key model systems for understanding the basic biology of malaria parasites. Cell and molecular parasitology have made much progress in identifying genes underpinning interactions between malaria parasites, hosts, and vectors. However, little attention has been paid to the evolutionary genetics of parasites, which provides context for identifying potential therapeutic targets and for understanding the selective forces shaping parasites in natural populations. Additionally, understanding the relationships between species, subspecies, and strains, is necessary to maximize the utility of rodent malaria parasites as medically important infectious disease models, and for investigating the evolution of host-parasite interactions. Results Here, we collected multi-locus sequence data from 58 rodent malaria genotypes distributed throughout 13 subspecies belonging to P. berghei, P. chabaudi, P. vinckei, and P. yoelii. We employ multi-locus methods to infer the subspecies phylogeny, and use population-genetic approaches to elucidate the selective patterns shaping the evolution of these organisms. Our results reveal a time-line for the evolution of rodent Plasmodium and suggest that all the subspecies are independently evolving lineages (i.e. species). We show that estimates of species-level polymorphism are inflated if subspecies are not explicitly recognized, and detect purifying selection at most loci. Conclusions Our work resolves previous inconsistencies in the phylogeny of rodent malaria parasites, provides estimates of important parameters that relate to the parasite’s natural history and provides a much-needed evolutionary context for understanding diverse biological aspects from the cross-reactivity of immune responses to parasite mating patterns.

Published

2012